FR2651365A1 - Protective grating - Google Patents

Abstract

The invention relates to a grating for protecting the tube bundles of steam condensers against erosion. It comprises a grating body (1) adapted to the dimensions of the erosive attack surface of the tubes of the steam condenser. A plurality of cylindrical tubular elements (2) form a grille (3), these tubular elements having a lengthwise dimension parallel to the lengthwise dimension of the grating body. Application to the protection of tube bundles of steam condensers of pressurised water nuclear reactors against erosion.

Description

 The invention relates to a protective grating against erosion of tube bundles of steam condensers of pressurized water nuclear reactors of electric power generation plants.

 During recent systematic inspection campaigns on the steam condensers of pressurized water nuclear reactors, the extent of erosion damage caused by the impact of water drops on the peripheral tubes of bundles has been noted. condensation.

 Various means currently make it possible to act against this phenomenon, such as, for example, increasing the resistance to erosion of the constituent materials of the tubes, increasing their thickness .... These measures, although beneficial, do not allow the oppose directly the cause of the damage thus caused.

 The object of the present invention is to eliminate the above-mentioned drawbacks by the use of a protective grating-type system designed to eliminate, or at least to very greatly reduce, the impact of drops of water on the tubes. condensation beam devices and their damaging effects on them.

 Another object of the present invention is also the implementation of a type of erosion protection system of steam condenser tube bundles causing minimal insertion load losses, for a plurality of the vapor stream on said condenser tubes.

 The erosion protection bundle of the steam condenser tube bundles, object of the present invention, is remarkable in that it comprises a grating body adapted to the dimensions of the base of the steam condenser tube tubes. . A plurality of cylindrical tubular elements is fixed to the grating body to form a grid, the tubular elements forming this grid having a longitudinal dimension parallel to the longitudinal dimension of the grating body.

 The erosion protection system of steam condenser tube bundles, which is the subject of the invention, is applicable to the protection of tube bundles of steam condensers of pressurized water nuclear reactors for example.

The system of grating-type protection against erosion of steam condenser tube bundles, object of the present invention, will be better understood from reading the description below and from the observation of the drawings in which
FIG. 1 represents a front view of a grating type protection system which is the subject of the invention,
FIG. 2 represents a sectional view of the grating type protection system according to the sectional plane AA of FIG. 1,
FIG. 3 represents at its points a) and b) a mounting mode of a grating type protection system, object of the invention, for testing to determine the insertion load loss as a function of the incidence of the vapor stream on the condenser tubes,
FIG. 4a shows three types of blade reference gratings making it possible to carry out comparative measurements of pressure drop for the grating, object of the invention, the gratings with blades being represented in cross-section at the scale 1,
FIGS. 4b, 4c, 4d and 4e show insertion pressure loss graphs as a function of the static pressure, as a function of the dynamic pressure for different steam vein incidence values, relative to a protection system. slatted type respectively.

 A more detailed description of a system of grating type protection against erosion of steam condenser tube bundles, object of the invention, will be given in connection with Figure 1.

 In accordance with the above-mentioned figure, the erosion protection grating type system of steam condenser tube bundles, object of the invention, comprises a grating body 1 adapted to the dimensions of the attack surface of the tubes of the steam condenser. The grating body may be constituted by a stainless steel frame for example.

 In addition, a plurality of cylindrical tubular elements 2 is provided, to form a grid 3 to be placed in the path of the steam stream driven to the steam condenser tubes.

 The steam stream is normally delivered in the application considered by a low pressure turbine, this vapor comprising water droplets that can reach speeds of between 100 and 150 m / second.

 Preferably, the tubular elements 2 forming the grid 3 have a longitudinal dimension parallel to the longitudinal dimension of the grating body.

 According to an advantageous characteristic of the grating type system, object of the invention, and as shown in FIG. 2, in a sectional view along the sectional plane AA of FIG. 1, the grid 3 can be formed by a plurality of rows of tubular elements 2. Preferably, by way of non-limiting example, the tubular elements are arranged in staggered rows.

 In an advantageous embodiment, the grid 3 constituting the grating according to the subject of the invention has three rows of tubular elements. This number is, of course, not limiting and experimental results have shown that a number of rows equal to two to constitute the grid 3 could also be considered.

According to another characteristic of the grating-type system, object of the invention, for a diameter of the tubular elements, the latter are distant, on the same row, of a pitch, noted pt, longitudinal inter-axis of the tubular elements equal to 2 x
In addition, as also shown in FIG. 2, two successive rows of tubular elements constituting the grid 3 have their mean axis shown in phantom in FIG. 2, at a distance of not greater than 1, Where x) represents the diameter of the aforementioned tubular elements.

 Of course, the tubular elements consist of a material inert with water vapor and drops of water. In particular, the constituent material of the tubular elements may be stainless steel.

 As furthermore shown in FIG. 1, to ensure the maintenance of the grating type system, object of the invention, above the bundles of condensation tubes, the bundles of condensation tubes having been dotted in FIG. 2, the latter comprises support plates 10 fixed to the slatted body and to the flanks of the condenser.

 Taking into account the embodiment of the grating type system, object of the invention, as represented in FIGS. 1 and 2, tests were carried out under the conditions as represented in FIG. 3, the aforementioned tests having been carried out in FIGS. conditions below.

In the description below, the different variables and notations designate the following parameters:
2
p V: Dynamic pressure of the speed (Pa)
A h: Loss of charge of the vein and the grid (Pa)
(Grating + vein)
A h: Loss of charge of the empty vein (Pa)
(without the grating)
3 z
A h3: Load loss of the grid = nh - A h (Pa) ir = A h: Coefficient of real pressure loss of the grid:: Angle of incidence of the direction of the fluid
(steam)
Sg = nh: Overall load loss coefficient (5 vein + ir) PV2
The grating type system, object of the invention, during the tests was placed in a plywood test vein connected to the suction of a blower.

 The aforementioned vein comprises, as shown in FIG. 3, an inlet convergent noted A, a measuring chamber upstream of the grating-type system of the invention, denoted B, a connecting element denoted F whose The articulation is variable in angular orientation, the protective grating type system denoted C, a pressure measuring chamber downstream of the grating protection system denoted D, a connection element E of the test vein to the suction pipe of the fan.

 The test vein had a width of 402 mm and a height of 730 mm.

 The upstream measurement section, denoted Pa, was located 500 mm from the input section of the feed convergent and the downstream measurement section, denoted Pb, was located 650 mm from the leading edge of the grating-type system. protection according to the invention. The two pressure measuring sections Pa and Pb, as shown in FIG. 3, were equipped with a PRANDTL tube.

 The incidence of flow vein with respect to the leading edge of the protective grating type system, object of the invention, was capable of adjustment for incidence values of 180O to -45 ".

The tests were carried out for the angles below, 1800, -15, -30 "and 45o.

 The pressure drop of the test vein was determined beforehand in the absence of the protective grating type system object of the invention, for an angle of incidence of the flow equal to 1800.

 The whole installation was supplied with air at room temperature. The two static pressure taps of the PRANDTL tubes in Pa and Pb in FIG. 3 were connected to an inclined manometer permitting the reading of the pressure difference between the two sections, for the four successive angles of incidence mentioned above.

 The PRANDTL tube, positioned in the measurement section upstream of the grating type system, which is the subject of the invention, also made it possible to measure the dynamic pressure of the flow.

The pressure loss specific to the protective grating type system, object of the invention, is given by the relationship
3 1 2
A h (grating) = A h (total) - A h (test vein).

For each configuration, the pressure drop is measured for dynamic pressures between 15 and 130 Pa, which corresponds to actual speeds in the condenser between 25 m / s and 70 m / s.

 The cases where the flow has an incidence different from 1800 with respect to the protective grating type system, object of the invention, were taken into consideration, the incidence of 1800 being that of an orthogonal descending vertical vapor flow. in the plane of the grid G constituting the grating according to the invention.

 The measurements made were carried out, on the one hand, in absolute measurements relative to the protective grating type system, according to the invention, and, on the other hand, in relative measurements with respect to different models of slatted gratings, said grating reference, as shown in scale 1 in Figure 4a, models corresponding to configurations shown in A, B, C corresponding to respective types, type A, type B, type C grating reference. In all of the aforementioned models or types of reference grating, the blades were all inclined at 45 "with respect to an incidence at 1800 of the steam flow vein.

 As shown by the test results, the coefficient of pressure loss 5 r, 5 g is constant from a dynamic pressure of 140 Pa corresponding to a vapor speed of 75 m / s and a specific gravity mass. 0.05 kg / m3.

 The curves of the measurements below, as represented in FIGS. 4b, 4c, 4d, 4e, can be extrapolated linearly up to speeds of the order of 100 mls observed in the condensers.

 The effect of the portion of vein disposed upstream of the grating type system, object of the invention, on this coefficient of pressure loss is low, of the order of 2%, and the measurements made during the tests can be extrapolated under good conditions to real condensers.

 The results of the above measurements are given in FIGS. 4b, 4c, 4d and 4e below.

Figure 4b gives the values of the overall pressure drop
Ah 1 for 1800, -15, -30 "and -450 incidence flows.

In the aforementioned FIG. 4b, the abscissa axis is graduated in
Pascal and the y-axis respectively in dynamic pressures in
Pascal and corresponding linear velocities of the test fluid.

 FIG. 4c shows the evolution of the overall load loss coefficient ig for the different incidences of flow upstream of the grating type system, object of the invention. The coefficient varies from 3.12 for an incidence of 1800 to 4 for an incidence of -45. The variation of the coefficients g r and 5 g for a flow at 1800 is also represented in FIG. 4c. The difference between these coefficients is at most 2%.

 FIG. 4 d shows the real pressure drop coefficient gr for a flow at 1800, the abscissa axis of FIG. 4 d being graduated in Pascal dynamic pressures and in corresponding speeds of the test fluid, and y-axis in values of actual load-loss coefficient 5 r.

 In this same FIG. 4d, the coefficients of real pressure loss r are also represented for the three types A, B, C of gratings of reference constituted by the gratings with blades.

 Similarly, FIG. 4e shows a comparison of the overall pressure drop coefficients 5 g between the protective grating type system, object of the invention, and one of the reference gratings, the type C grating providing the lowest pressure drop among the reference gratings.

 The following values are obtained - for a flow at + 45, grating according to the invention, 5 g = 4, - for a flow at + 45, grating of reference, 5 g = 3,8, - for a flow at - 45, grating of reference, gg = 8.

Thus, an erosion protection grating system of vapor condenser tube bundles has been described which is particularly suitable since, for a speed of 100 m / s of the steam or test fluid upstream, the coefficients of loss of following 5 r load were obtained
grating according to the invention 5 r = 3.12
grating ir reference = 4.25.

 For incidences of vapor flow or test fluid other than 1800, the maximum coefficient of pressure loss of the grating according to the invention is 4, that of the type C grating of reference being 8.

 Finally, an effective realization of a grating according to the object of the invention could be carried out, the grating actually made having an area of 6 m2.

 This embodiment has given all satisfaction from the point of view of operation, in accordance with the measurements made previously.

Claims (7)

 1. Grating protection against erosion of steam condenser tube bundles, characterized in that it comprises - a grating body (1) adapted to the dimensions of the attack surface  tubes of the steam condenser, - a plurality of cylindrical tubular elements (2) forming a grid (3),  said tubular elements forming a grid having a dimension  longitudinal parallel to the longitudinal dimension of the body of  grating.  2. Grating according to claim 1, characterized in that said grid (3) is formed by a plurality of rows of tubular elements (2), the tubular elements being arranged in staggered rows.  3. Grating according to claim 2, characterized in that it comprises three rows of tubular elements.  4. Grating according to one of claims 2 or 3, characterized in that, for a diameter 3 of said tubular elements, the latter are distant, in the same row, a pitch pt inter-axis lontidudinal equal to 2 x  5. grating according to one of claims 2 to 4, characterized in that two successive rows have their mean axis remote from 1.25 x where 8 represents the diameter of the tubular elements.  6. grating according to one of the preceding claims, characterized in that said tubular elements are made of a material such as stainless steel.  7. Grating according to one of claims 1 to 6, characterized in that, to ensure the maintenance of the latter above the bundles of condensation tubes, said grating comprises support plates attached to the slatted body and on the flanks of the condenser.